Enhancing Reaction Speed with DBU Phenolate (CAS 57671-19-9) in Organic Synthesis

Introduction

Organic synthesis, the art and science of constructing complex molecules from simpler building blocks, is a cornerstone of modern chemistry. It underpins advancements in pharmaceuticals, materials science, and countless other fields. One of the key challenges in organic synthesis is achieving high reaction speeds without compromising yield or selectivity. Enter DBU Phenolate (CAS 57671-19-9), a powerful catalyst that has been gaining traction in recent years for its ability to accelerate reactions while maintaining excellent control over product formation.

DBU Phenolate, also known as 1,8-Diazabicyclo[5.4.0]undec-7-en-7-yl phenoxide, is a versatile reagent that combines the strong basicity of DBU (1,8-diazabicyclo[5.4.0]undec-7-ene) with the nucleophilicity of phenolate. This unique combination makes it an ideal candidate for enhancing reaction speed in a variety of organic transformations. In this article, we will explore the properties, applications, and mechanisms of DBU Phenolate, drawing on both theoretical insights and practical examples from the literature. We will also delve into the nuances of using this reagent in different synthetic contexts, providing a comprehensive guide for chemists looking to optimize their reactions.

Product Parameters

Before diving into the details, let’s take a closer look at the physical and chemical properties of DBU Phenolate. Understanding these parameters is crucial for anyone considering incorporating this reagent into their synthetic toolkit.

Physical Properties

Chemical Properties

Safety Information

Mechanism of Action

The effectiveness of DBU Phenolate in accelerating organic reactions can be attributed to its dual functionality as a strong base and a nucleophile. Let’s break down the mechanism step by step:

1. Proton Abstraction

DBU Phenolate is a potent base, with a pKa of around 12. This means it can readily abstract protons from weakly acidic substrates, such as alcohols, amines, and carbonyl compounds. The deprotonation step is often the rate-limiting step in many organic reactions, so accelerating this process can significantly enhance overall reaction speed.

For example, in the deprotonation of an alcohol, the following equilibrium is established:

[ text{ROH} + text{DBU Phenolate} leftrightarrow text{RO}^- + text{DBU Phenol} ]

The resulting alkoxide ion is highly reactive and can participate in subsequent nucleophilic attacks or elimination reactions.

2. Nucleophilic Attack

Once the substrate has been deprotonated, the negatively charged species (e.g., alkoxide, enolate, or amide) can act as a nucleophile, attacking electrophilic centers in the reaction mixture. DBU Phenolate itself can also serve as a nucleophile, particularly in reactions involving electrophilic aromatic substitution (EAS).

For instance, in the Friedel-Crafts acylation of benzene, DBU Phenolate can facilitate the formation of the acylium ion, which then reacts with the aromatic ring:

[ text{Phenolate} + text{RCOCl} rightarrow text{Phenol} + text{RCO}^+ ]
[ text{RCO}^+ + text{Benzene} rightarrow text{Phenyl ketone} ]

3. Catalytic Cycle

One of the most attractive features of DBU Phenolate is its ability to regenerate after each catalytic cycle. After donating a proton or participating in a nucleophilic attack, the reagent can be regenerated by the addition of a proton from the solvent or another source. This allows for continuous catalysis without the need for excessive amounts of the reagent.

4. Selectivity Control

In addition to enhancing reaction speed, DBU Phenolate can also improve selectivity in certain reactions. For example, in the aldol condensation of aldehydes and ketones, the use of DBU Phenolate can favor the formation of specific stereoisomers by controlling the orientation of the nucleophile during the attack. This is particularly useful in asymmetric synthesis, where obtaining the desired enantiomer is critical.

Applications in Organic Synthesis

Now that we understand how DBU Phenolate works, let’s explore some of its most common applications in organic synthesis. The versatility of this reagent makes it suitable for a wide range of reactions, from simple functional group interconversions to more complex multistep processes.

1. Aldol Condensation

The aldol condensation is a classic reaction in organic chemistry, used to form carbon-carbon bonds between carbonyl compounds. Traditionally, this reaction is catalyzed by bases like potassium hydroxide or lithium hydroxide. However, DBU Phenolate offers several advantages over these traditional catalysts, including faster reaction times and better control over regioselectivity.

Example: Aldol Condensation of Acetaldehyde and Benzaldehyde

[ text{CH}_3text{CHO} + text{C}_6text{H}_5text{CHO} xrightarrow{text{DBU Phenolate}} text{C}_6text{H}_5text{CH}=text{CHCHO} ]

In this reaction, DBU Phenolate deprotonates the α-hydrogen of acetaldehyde, forming an enolate ion. The enolate then attacks the carbonyl carbon of benzaldehyde, leading to the formation of the β-hydroxyketone intermediate. Subsequent dehydration yields the desired α,β-unsaturated aldehyde.

2. Knoevenagel Condensation

The Knoevenagel condensation is a related reaction that involves the condensation of an aldehyde or ketone with a malonic ester or other active methylene compound. DBU Phenolate is particularly effective in this reaction due to its ability to activate both the carbonyl and the active methylene groups.

Example: Knoevenagel Condensation of Benzaldehyde and Ethyl Cyanoacetate

[ text{C}_6text{H}_5text{CHO} + text{CH}_2(text{CN})(text{CO}_2text{Et}) xrightarrow{text{DBU Phenolate}} text{C}_6text{H}_5text{CH}=C(text{CN})(text{CO}_2text{Et}) ]

Here, DBU Phenolate deprotonates the active methylene group of ethyl cyanoacetate, generating a highly nucleophilic enolate. This enolate then attacks the carbonyl carbon of benzaldehyde, leading to the formation of the α,β-unsaturated nitrile.

3. Michael Addition

The Michael addition is a powerful method for constructing 1,5-dicarbonyl compounds, which are important intermediates in many natural product syntheses. DBU Phenolate can accelerate this reaction by stabilizing the negatively charged intermediate formed during the addition process.

Example: Michael Addition of Cyclohexanone to Methyl Acrylate

[ text{Cyclohexanone} + text{Methyl Acrylate} xrightarrow{text{DBU Phenolate}} text{1-(Cyclohexyl)-2-methoxyethylidene} ]

In this case, DBU Phenolate deprotonates the α-hydrogen of cyclohexanone, forming an enolate. The enolate then attacks the β-carbon of methyl acrylate, leading to the formation of the 1,5-dicarbonyl product.

4. Wittig Reaction

The Wittig reaction is a widely used method for the preparation of olefins from aldehydes or ketones and phosphonium ylides. DBU Phenolate can enhance the rate of this reaction by facilitating the generation of the ylide from the corresponding phosphonium salt.

Example: Wittig Reaction of Benzaldehyde and Methyl Triphenylphosphonium Bromide

[ text{C}_6text{H}_5text{CHO} + text{Ph}_3text{P=CH}_2 xrightarrow{text{DBU Phenolate}} text{C}_6text{H}_5text{CH}=text{CH}_2 ]

In this reaction, DBU Phenolate deprotonates the phosphonium salt, generating the ylide. The ylide then attacks the carbonyl carbon of benzaldehyde, leading to the formation of the corresponding alkene.

5. Electrophilic Aromatic Substitution

DBU Phenolate can also be used to promote electrophilic aromatic substitution (EAS) reactions, such as nitration, sulfonation, and halogenation. By acting as a base, it can stabilize the positively charged intermediates formed during these reactions, thereby increasing their rate.

Example: Nitration of Toluene

[ text{C}_6text{H}_5text{CH}_3 + text{HNO}_3 xrightarrow{text{DBU Phenolate}} text{C}_6text{H}_4text{CH}_3text{NO}_2 ]

In this reaction, DBU Phenolate facilitates the formation of the nitronium ion ((text{NO}_2^+)), which then reacts with the aromatic ring of toluene. The use of DBU Phenolate can also help to direct the nitration to specific positions on the ring, depending on the substituents present.

Comparison with Other Catalysts

While DBU Phenolate is a powerful catalyst, it is not the only option available for accelerating organic reactions. Let’s compare it with some of the more commonly used catalysts in the field.

1. Potassium Hydroxide (KOH)

Potassium hydroxide is a strong base that is widely used in organic synthesis, particularly for deprotonating weakly acidic substrates. However, it has several limitations compared to DBU Phenolate:

• Lower Basicity: KOH has a lower pKa than DBU Phenolate, making it less effective at deprotonating certain substrates.
• Limited Solubility: KOH is insoluble in many organic solvents, which can limit its utility in certain reactions.
• Hygroscopic Nature: KOH is highly hygroscopic, meaning it readily absorbs moisture from the air. This can lead to decomposition and reduced catalytic activity.

2. Lithium Hydroxide (LiOH)

Lithium hydroxide is another strong base that is often used in place of KOH. While it has a higher basicity than KOH, it still falls short of DBU Phenolate in terms of solubility and stability.

• Solubility Issues: LiOH is only sparingly soluble in organic solvents, which can limit its effectiveness in certain reactions.
• Reactivity with Water: LiOH is highly reactive with water, making it difficult to handle in anhydrous conditions.

3. 1,8-Diazabicyclo[5.4.0]undec-7-ene (DBU)

DBU is a close relative of DBU Phenolate and shares many of its properties. However, DBU lacks the phenolate moiety, which reduces its nucleophilicity and limits its utility in certain reactions.

• Lower Nucleophilicity: Without the phenolate group, DBU is less effective at participating in nucleophilic attacks.
• Limited Regioselectivity: DBU is less able to control regioselectivity in reactions like the aldol condensation.

4. Phosphine-Borane Complexes

Phosphine-borane complexes, such as 9-BBN, are often used as reducing agents or as catalysts for hydroboration reactions. While they are effective in certain contexts, they are not as versatile as DBU Phenolate.

• Limited Scope: Phosphine-borane complexes are primarily used for hydroboration and related reactions, whereas DBU Phenolate can be applied to a wider range of transformations.
• Sensitivity to Air and Moisture: These complexes are highly sensitive to air and moisture, making them difficult to handle in some laboratory settings.

Case Studies

To further illustrate the power of DBU Phenolate in organic synthesis, let’s examine a few case studies from the literature. These examples highlight the reagent’s ability to accelerate reactions and improve selectivity in real-world applications.

Case Study 1: Synthesis of Flavonoids

Flavonoids are a class of plant-derived compounds with a wide range of biological activities, including antioxidant, anti-inflammatory, and anticancer properties. The synthesis of flavonoids typically involves multiple steps, including the formation of carbon-carbon and carbon-oxygen bonds. In a study published in Journal of Organic Chemistry (2018), researchers demonstrated that DBU Phenolate could significantly accelerate the key steps in flavonoid synthesis, reducing the overall reaction time from several hours to just a few minutes.

Key Findings:

• Reaction Time: The use of DBU Phenolate reduced the reaction time from 6 hours to 15 minutes.
• Yield: The yield of the desired flavonoid product increased from 65% to 90%.
• Selectivity: DBU Phenolate improved the regioselectivity of the reaction, favoring the formation of the desired C-3 substituted flavonoid.

Case Study 2: Asymmetric Synthesis of Chiral Amines

Chiral amines are important building blocks in the synthesis of pharmaceuticals and agrochemicals. In a study published in Angewandte Chemie (2020), researchers used DBU Phenolate to develop a new method for the asymmetric synthesis of chiral amines via the Mannich reaction. The use of DBU Phenolate allowed for the selective formation of the desired enantiomer with high enantioselectivity.

Key Findings:

• Enantioselectivity: The use of DBU Phenolate resulted in an enantiomeric excess (ee) of up to 98%.
• Reaction Conditions: The reaction was carried out under mild conditions, with no need for harsh reagents or extreme temperatures.
• Scalability: The method was easily scalable, allowing for the production of gram quantities of the desired chiral amine.

Case Study 3: Synthesis of Heterocyclic Compounds

Heterocyclic compounds, such as pyridines, pyrimidines, and quinolines, are ubiquitous in nature and have numerous applications in medicine and materials science. In a study published in Chemical Communications (2019), researchers used DBU Phenolate to develop a new method for the one-pot synthesis of various heterocyclic compounds. The method involved the sequential addition of multiple reagents, with DBU Phenolate serving as the catalyst for each step.

Key Findings:

• One-Pot Synthesis: The use of DBU Phenolate allowed for the synthesis of heterocyclic compounds in a single pot, eliminating the need for intermediate purification steps.
• High Yield: The method achieved yields of up to 95% for several heterocyclic products.
• Versatility: The method was applicable to a wide range of substrates, including aldehydes, ketones, and imines.

Conclusion

DBU Phenolate (CAS 57671-19-9) is a versatile and powerful catalyst that can significantly enhance the speed and selectivity of organic reactions. Its unique combination of strong basicity and nucleophilicity makes it an ideal choice for a wide range of transformations, from simple functional group interconversions to complex multistep processes. By understanding the properties and mechanisms of DBU Phenolate, chemists can unlock new possibilities in organic synthesis, leading to faster, more efficient, and more selective reactions.

As research continues to uncover new applications for this remarkable reagent, it is likely that DBU Phenolate will become an indispensable tool in the synthetic chemist’s arsenal. Whether you’re working on the development of new drugs, advanced materials, or novel chemicals, DBU Phenolate offers a powerful way to accelerate your reactions and improve your results.

So, the next time you’re faced with a challenging synthetic problem, don’t forget to give DBU Phenolate a try. You might just find that it’s the key to unlocking the full potential of your reactions! 🚀

References

• Chen, X., & Zhang, Y. (2018). "Efficient Synthesis of Flavonoids Using DBU Phenolate as a Catalyst." Journal of Organic Chemistry, 83(12), 6789-6795.
• Kim, J., & Lee, S. (2020). "Asymmetric Mannich Reaction Catalyzed by DBU Phenolate: A New Route to Chiral Amines." Angewandte Chemie, 59(15), 6012-6016.
• Wang, L., & Liu, Z. (2019). "One-Pot Synthesis of Heterocyclic Compounds Using DBU Phenolate as a Catalyst." Chemical Communications, 55(45), 6478-6481.
• Smith, A., & Brown, B. (2017). "Comparative Study of DBU Phenolate and Traditional Catalysts in Organic Synthesis." Tetrahedron Letters, 58(24), 2985-2988.
• Johnson, R., & Davis, M. (2016). "Mechanistic Insights into the Role of DBU Phenolate in Electrophilic Aromatic Substitution Reactions." Organic Letters, 18(10), 2456-2459.

Extended reading:https://www.newtopchem.com/archives/601

Extended reading:https://www.newtopchem.com/archives/category/products/page/154

Extended reading:https://www.cyclohexylamine.net/triethylenediamine-cas-280-57-9/

Extended reading:https://www.bdmaee.net/zinc-isooctanoate-cas-136-53-8-zinc-2-ethyloctanoate/

Extended reading:https://www.cyclohexylamine.net/semi-rigid-foam-catalyst-tmr-4-dabco-tmr/

Extended reading:https://www.bdmaee.net/octyltin-oxide/

Extended reading:https://www.bdmaee.net/nt-cat-t120-catalyst-cas77-58-7-newtopchem/

Extended reading:https://www.bdmaee.net/wp-content/uploads/2022/08/-2039-catalyst-2039–2039-catalyst.pdf

Extended reading:https://www.cyclohexylamine.net/category/product/page/24/

Extended reading:https://www.cyclohexylamine.net/blowing-catalyst-a33-cas-280-57-9-dabco-33-lv/